Development of a kinetic model for low temperature Fischer-Tropsch synthesis

Abstract: Globally, there is a need to replace our dependence on fossil fuels as the main source of energy.This requires a shift towards renewable and sustainable alternatives. The well-established Fischer-Tropsch (FT) synthesis is a potential process route to produce liquid fuels and speciality chemicals and address this challenge. FT synthesis is a polymerisation reaction in which syngas, a mixture of CO and H 2 , is converted to hydrocarbon products ranging from methane to wax when low temperature conditions are used… Show more

“…Hence, it was predicted that the selectivity towards jet fuel (C 8 –C 16 ) at the RNC catalyst would be greater in comparison to the FTS products, in particular, liquid fuels. Besides, from a thermodynamic point of view, methane is the most probable product in FTS, which is according to the reports by Davies et al and Zaffran et al , 47,48 and the Δ G results that were extracted from MD computations confirm this. The MD simulation results illustrate that Δ G for methane formation, 0.29 and 0.26 kcal mol −1 in NC and RNC catalysts, respectively, have the lowest values and Ru boosts its formation.…”

Promoting jet fuel production by utilizing a Ru-doped Co-based catalyst of Ru-Co@C(Z-d)@Void@CeO₂ in Fischer Tropsch synthesis

“…Hence, it was predicted that the selectivity towards jet fuel (C 8 –C 16 ) at the RNC catalyst would be greater in comparison to the FTS products, in particular, liquid fuels. Besides, from a thermodynamic point of view, methane is the most probable product in FTS, which is according to the reports by Davies et al and Zaffran et al , 47,48 and the Δ G results that were extracted from MD computations confirm this. The MD simulation results illustrate that Δ G for methane formation, 0.29 and 0.26 kcal mol −1 in NC and RNC catalysts, respectively, have the lowest values and Ru boosts its formation.…”

Promoting jet fuel production by utilizing a Ru-doped Co-based catalyst of Ru-Co@C(Z-d)@Void@CeO₂ in Fischer Tropsch synthesis

“…This remark is important for proper understanding of the proposed living growth mechanism, as diffusion can control the chain length, as the effective-constants fall with the chain size. Particularly, Davies and Möller observed that the product distribution might be controlled by the chemical equilibrium, while the hydrocarbon yield was kinetically controlled. In this case, the reduction of the kinetic rate constants might indicate the occurrence of other parallel reactions besides chain growth.…”

Fischer–Tropsch Synthesis Model Involving the Living Growth of Carbon Chains

“…On the other hand, WGS and Boudouard reactions are less exothermic compared to the hydrogenation reactions. Based on the Gibbs free energy analysis, it can be speculated that higher temperatures favor the WGS and Boudouard reactions and the formation of short-chain products. , Davies et al . developed an equilibrium-constrained kinetic model to predict the hydrocarbon distribution (Figure a)–d).…”

“…Based on the Gibbs free energy analysis, it can be speculated that higher temperatures favor the WGS and Boudouard reactions and the formation of short-chain products. 147,148 Davies et al 149 developed an equilibrium-constrained kinetic model to predict the hydrocarbon distribution (Figure 25a)−d). It was found that the product distribution was equilibrium-controlled, while the yield of hydrocarbon products was kinetically controlled.…”

“…(a–d): Carbon distribution of paraffins and olefins from CO hydrogenation as a function of reaction temperature and pressure; (e) and (f): Selectivity of hydrocarbon products and CO 2 conversion at different temperatures and pressures; (g) Δ r G of RWGS and FTS reactions during CO 2 hydrogenation; (h) Δ r G of CO and hydrocarbon products formation during CO 2 hydrogenation. Reproduced from refs − with permissions from Elsevier and Wiley-VCH.…”

An Overview on Dynamic Phase Transformation and Surface Reconstruction of Iron Catalysts for Catalytic Hydrogenation of CO_x for Hydrocarbons